historically, scientists have used their knowledge of atomic properties to develop and refine atomic...

Historically, scientists have used their knowledge of atomic properties to develop and refine atomic models. Today, this knowledge is applied to various research techniques.

UNIT 2

Chapter 3: Atomic Models and Properties of Atoms

Scientists can now determine colour patterns of ancient bird feathers by identifying elements present in fossils of the birds.


UNIT 2 Section 3.1

3.1 Developing a Nuclear Model of the Atom


Dalton’s model (1808)

Thomson’s model (1904)

Rutherford’s model (1911)

Bohr’s model (1913)

quantum mechanical model (present)

UNIT 2 Section 3.1

Reviewing the Atomic Models of Dalton and Thomson


John Dalton’s model of the atom:

• marked the beginning of a new way of explaining matter• matter was described as being composed of small,

indivisible spheres, which Dalton called atoms

Why did the discovery of subatomic particles like electrons require a new atomic model?

Dalton envisioned atoms as hard, solid spheres.

UNIT 2 Section 3.1

Reviewing the Atomic Models of Dalton and Thomson

Thomson’s “plum pudding” model of the atom.


J.J. Thomson’s model of the atom:

• incorporated his discovery of the electron, using cathode ray tubes

• an atom is a positively charged spherical mass with negatively charged electrons embedded within

Rutherford’s experimental observations required a new atomic model.

UNIT 2 Section 3.1

Rutherford’s Experiments with Alpha Particles


Expectation (Thomson’s model):• particles pass through or some

slightly deflected

Observation:• some particles deflected at

large angles

Alpha particles were aimed at gold foil. The scattering of the alpha particles was monitored.

Rutherford’s model of the atom:

UNIT 2 Section 3.1

Rutherford’s Atomic Model

The nuclear, or planetary model, of the atom.


• large deflections of particles proposed to be due to presence of an electric field at the centre of the atom

• an atom has a positively charged nucleus at the centre with electrons in motion surrounding the nucleus

UNIT 2 Section 3.1

The Limitations of Rutherford’s Atomic Model


Based on the understanding of physics at the time, for an electron in motion around a central core:

• radiation must be emitted, so it was expected that a continuous spectrum of light energy was being given off

• because of radiation, the electron would lose energy and its orbit would decrease until it spiraled into the nucleus, destroying the atom

UNIT 2 Section 3.1

Rethinking Atomic Structure Based on the Nature of Energy


Light is one form of electromagnetic radiation, whichtravels through space as waves

Electromagnetic waves:• have frequency, wavelength, and amplitude• interact with matter in discrete particles called photons

When atoms are excited due to absorption of energy, they emit light as they lose energy and return to a non-excited state.

UNIT 2 Section 3.1

Atomic Spectra

Each element has a characteristic line spectrum.


Atoms of each element emit light of particular wavelengths called a line spectrum or emission spectrum.

UNIT 2 Section 3.1

The Bohr Model of the Hydrogen Atom


• are in circular orbits

• can only exist in certain “allowed” orbits or energy levels (energy of electrons is quantized)

• do not radiate energy while in one orbit

• can jump between orbits by gaining or losing a specific amount of energy

Niels Bohr set out to explain the stability of the nuclear model of the atom. In this model, electrons

UNIT 2 Section 3.1

Bohr’s Atomic Model Explains the Line Spectrum of Hydrogen


• Calculated wavelengths of the possible energies of photons that could be emitted from an excited hydrogen atom (transitions from n = 6, 5, 4, and 3 to n = 2) corresponded with hydrogen’s visible line spectrum

Limitations

• could only explain single-electron systems (H, He+, Li2+)

Today’s quantum mechanical model of the atom incorporates the wave properties of electrons.

UNIT 2 Section 3.2

3.2 The Quantum Mechanical Model of the Atom

An electron density diagram represents an atomic orbital.


Wave functions, initially described by Erwin Schrodinger, represent a region in space around a nucleus where an electron will be found. This region of space is called an atomic orbital

14

Many scientists contributed to the development of the quantum mechanical model of the atom.

– Bohr– Planck– DeBroglie– Heisenberg– Schrodinger– Pauli

UNIT 2 Section 3.2

The Quantum Mechanical Model of the Atom

The circle does not represent a real boundary.


Atomic orbitals can be visualized as “fuzzy clouds”

• The higher the density of the “cloud,” the higher the probability of finding an electron at that point.

• The cloud has no definite boundary.

• The region where an electron will spend 90 percent of its time is depicted by drawing a circle.

HeisenbergThe Heisenberg uncertainty principle states that we cannot know

both the position and the momentum of an electron at the same time.

– Therefore, we do not know the exact path of the electron in an orbital but there is a probability of finding one in a certain space.

– Quantum mechanical model uses complex orbital shapes (electron clouds), volumes of space where electrons are likely to be found

UNIT 2 Section 3.1

Quantum Numbers Describe Orbitals


Electrons in the quantum mechanical model of the atom are described using quantum numbers.

Three quantum numbers describe the distribution of electrons in the atom and a fourth describes the behaviour of each electron.

Symbols for the four quantum numbers:

n l ml ms

UNIT 2 Section 3.2

The Principle Quantum Number, n


• Is the first quantum number

• Describes the energy level, or shell, of an orbital (the distance from orbital to nucleus)

• All orbitals with the same n value are in the same shell

• The larger the n value, the larger the size of the shell, the higher the energy

• Values can range from n = 1 to n = ∞

n = 1 first shelln = 2 second shelln = 3 third shelln = 4 fourth shell

UNIT 2 Section 3.2

The Orbital-Shape Quantum Number, l


• Is the second quantum number, also known as the angular momentum number

• Describes the shape of an orbital

• Refers to energy sublevels, or subshells (same n different l)

• Values depend on the value of n. They are positive integers from 0 to (n – 1)

• Each value is identified by a letter l = 0 sl = 1 pl = 2 dl = 3 f

An energy sublevel is identified by combining n with the orbital letter. For example, n = 2, l = 1: 2p sublevel

UNIT 2 Section 3.2

The Magnetic Quantum Number, ml

s, p, and d orbitals have characteristic shapes.


• Is the third quantum number

• Indicates the orientation of the orbital in space

• For a given l there are (2l +1) values for ml

• The total number of orbitals for an energy level is n2

UNIT 2 Section 3.2

The Spin Quantum Number, ms


• Is the fourth quantum number

• Describes the direction the electron is spinning in a magnetic field – clockwise or counterclockwise

• Two possible values: +½ or –½ - only 2 electrons possible in each subshell

To summarize:

UNIT 2 Section 3.2

Identifying Electrons Using Sets of Quantum Numbers


According to the Pauli exclusion principle:

• an orbital can have a maximum of two electrons

• two electrons in an orbital must have opposite spins

No two electrons of an atom have the same set of four quantum numbers.

What is the set of quantum numbers for an electron in a 2s orbital?

UNIT 2 Section 3.2

Answer on the next slide


n =2, l = 0, ml = 0, ms = +½

Section 3.2UNIT 2 Chapter 3: Atomic Models and Properties of Atoms

LEARNING CHECK

historically, scientists have used their knowledge of atomic properties to develop and refine atomic...

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